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Cell–cell recognition

December 18, 2023

Cell–cell recognition is a cell's ability to distinguish one type of neighboring cell from another.[1] This phenomenon occurs when complementary molecules on opposing cell surfaces meet. A receptor on one cell surface binds to its specific ligand on a nearby cell, initiating a cascade of events which regulate cell behaviors ranging from simple adhesion to complex cellular differentiation.[2] Like other cellular functions, cell-cell recognition is impacted by detrimental mutations in the genes and proteins involved and is subject to error. The biological events that unfold due to cell-cell recognition are important for animal development, microbiomes, and human medicine.

Two cells communicating via their respective surface molecules.

Fundamentals edit

Cell–cell recognition occurs when two molecules restricted to the plasma membranes of different cells bind to each other, triggering a response for communication, cooperation, transport, defense, and/or growth. Rather than induce a distal response, like secreted hormones may do, this type of binding requires the cells with the signalling molecules to be in close proximity with each other. These events can be grouped into two main categories: Intrinsic Recognition and Extrinsic Recognition.[3] Intrinsic Recognition is when cells that are part of the same organism associate.[3] Extrinsic Recognition is when the cell of one organism recognizes a cell from another organism, like when a mammalian cell detects a microorganism in the body.[3] The molecules that complete this binding consist of proteins, carbohydrates, and lipids, resulting in a variety of glycoproteins, lipoproteins, and glycolipoproteins.[3] Studies suggest glycan-glycan interactions, observed to be approximately 200-300pN, also may play a role in cell-cell recognition.[4] Complex carbohydrates, in particular, have been studied to be extremely integral in cell-cell recognition, especially when it is recognized by complementary carbohydrates. In order to ensure a proper binding site by checking the surrounding areas or securing a bond that was previously made complex carbohydrates and their complementary carbohydrates are able to create flexible interaction systems. These interactions, although observed to be weak, have been studied in a variety of test subjects including, but not limited to, mouse embryonal cells, corneal epithelial cells, and human embryonal carcinoma cells.[4]

Biological functions for intrinsic recognition edit

Growth and development edit

One of the more basic versions of cell-cell recognition for adhesion can be observed in sponges, the most primitive group in the animal kingdom. Sponges develop through the aggregation of individual cells into larger clusters. Through membrane-binding proteins and secreted ions, individual sponge cells are able to coordinate aggregation while preventing fusion between different species or even different individuals.[5] This was discovered when attempts to graft sponge cells from different species or individuals of the same species failed, while attempts using cells from the same individual merged successfully.[5] This is likely due to distinct cadherins, a calcium-binding membrane protein, expressed by different sponge species and individuals.[5] Cadherins are present in more complex organisms as well. In mouse embryos, E-cadherin on cell membranes is responsible for the adhesion of cells needed for embryonic compaction.[6]

Cell recognition for injury response edit

When a large multi-cellular organism sustains an injury, cell-cell recognition is often involved in bringing certain types of cells to the site of an injury. A common example of this is selectin-expressing cells in animals. Selectin is a receptor protein found on the membranes of leukocytes, platelet cells, and endothelial cells that binds membrane-bound glycans.[7] In response to an injury, endothelial cells will express selectin, which binds to glycans present on the leukocyte cell surface.[7] Platelet cells, which are involved in tissue repair, use their selectins to associate with leukocytes on the way to the endothelial cells.[7] Leukocytes then use their own selectins to recognize potential pathogens at the site of the injury.[7] In this manner, the appropriate cells are brought to the site of an injury to deal with immediate repair or invading microorganisms.[7]

Biological functions for extrinsic recognition edit

Pathogen recognition in the immune system edit

Cells with immune system recognition abilities include macrophages, dentritic cells, T cells, and B cells.[8] Cell–cell recognition is especially important in the innate immune system, which identifies pathogens very generally. Central to this process is the binding of pattern recognition receptors (PRRs) of phagocytes and pathogen-associated molecular patterns (PAMPs) in pathogenic microorganisms.[8] One type of PRR is a group of integral membrane glycoproteins called toll-like receptors (TLRs), which can recognize certain lipoproteins, peptidoglycan, CpG-rich DNA, and flagellar components in bacterial cells, as well as glycoproteins and phospholipids from protozoan parasites and conidia (fungal spores).[8] The binding of PAMPs to TLR proteins generally results in an internal signaling cascade including a number of phosphorylations, the adding of a phosphate group, and ubiquitinations, the adding of a small protein that marks molecules for degradation, that eventually leads to the transcription of genes related to inflammation.[8] The use of TLRs by cells in the innate immune system has led to an evolutionary battle between pathogenic cells developing different PAMPs that cannot be recognized and immune cells developing new membrane proteins that can recognize them.[8]

Bacterial ecology edit

Single-celled organisms can bind to each other through surface receptors for cooperation and competition. This has been widely observed in bacteria. For instance, bacteria can attach to each other through the binding of outer membrane proteins TraA and TraB to facilitate a process called outer membrane exchange (OME) that allows bacterial cells to swap membrane lipids, sugars, and toxins.[9] Cell recognition and OME can only be achieved if TraA and TraB variants from the same recognition group bind.[9] These interactions can generate the physiological diversity required for antibiotic resistance in bacterial populations.[10] The Escherichia coli membrane protein ChiA is involved in the process of contact-dependent inhibition (CDI) in which it binds to receptors on rival E.coli strains and releases a toxin that prevents growth of those strains while the inhibiting cell and members of that strain are protected.[9] The bacterium Proteus mirabilis uses the T6SS protein to initiate swarming and destruction of other bacterial colonies upon recognition, either by release of toxins or by release of signal proteins to other P. mirabilis cells.[9] The binding of bacterial surface receptors for adhesion has also been implicated in the formation of biofilms.[9]

Recognition of red blood cells edit

Blood types edit

Red blood cells contain antigens in their plasma membranes that distinguish them as part of a specific category of blood cell. These antigens can be polysaccharides, glycoproteins, or GPI (a glycolipid) -linked proteins.[11] Antigens range in complexity, from small molecules bound to the extracellular side of the phospholipid bilayer, to large membrane proteins that loop many times between both sides of the membrane.[11] The smaller polysaccharide antigens classify blood cells into types A, B, AB, and O, while the larger protein antigens classify blood cells into types Rh D-positive and Rh D-negative.[11] While the biological role of the correct blood type is unclear and may be vestigial, the consequences of incorrect blood types are known to be severe.[11] The same cells that recognize PAMPs on microbial pathogens may bind to the antigen of a foreign blood cell and recognize it as a pathogen because the antigen is unfamiliar.[11] It is not easy to classify red blood cell recognition as intrinsic or extrinsic, as a foreign cell may be recognized as part of the organism if it has the right antigens.

Detrimental mutations edit

TLR mutations edit

Mutations in mammalian receptor proteins can cause disorders in cell-cell recognition, increasing individual susceptibility to certain pathogens and chronic conditions. When mutations occurs in genes that code for TLRs, the proteins can lose the ability to bind with polysaccharides, lipids, or proteins on the cell wall or membrane of single-celled pathogens, resulting in a failure of the innate immune system to respond to infection that allows disease to develop rapidly. In particular, mutations in the genes for TLR2 and TLR4 have been frequently implicated in increased susceptibility to pathogens.[12] A threonine to cysteine mutation in the TRL2 gene has been connected to failure to recognize the Mycobacterium tuberculosis the causative agent of Tuberculosis meningitis.[13] The same mutation, T597C, was later observed consistently with the failure to recognize Mycobacterium leprae, the causative agent of Leprosy.[14] An Arginine to Glutamine mutation in TRL2, Arg753Gln, was connected to increased pediatric Urinary Tract Infections caused by gram-positive bacteria.[15] Multiple mutations in TLR4, Asp299Gly and Thr399Ile, were implicated in susceptibility to the bacterial pathogens that cause Periodontitis.[16] The connection of TLR mutations to Chron's Disease has also been investigated, but has not yielded conclusive evidence.[17] The common characteristic between these missense mutations is that the amino acid residues that are substituted have notably different side chain properties, which likely contributes to the defective TLR protein function.

References edit

  1. ^ Campbell, et al., Biology, Eighth Edition, 2008 Pearson Education Inc.
  2. ^ Schnaar, Ronald L., Research Goals, "Link", 1 May 2010
  3. ^ a b c d Ajit Varki and John B Lowe, Biological Roles of Glycans, Essentials of Glycobiology, 2nd Edition Cold Spring Harbor, 2009[page needed]
  4. ^ a b Bucior, Iwona; Burger, Max M (October 2004). "Carbohydrate–carbohydrate interactions in cell recognition". Current Opinion in Structural Biology. 14 (5): 631–637. doi:10.1016/j.sbi.2004.08.006. PMID 15465325.
  5. ^ a b c Fernàndez-Busquets, Xavier; Burger, Max M. (1999). "Cell adhesion and histocompatibility in sponges". Microscopy Research and Technique. 44 (4): 204–218. doi:10.1002/(SICI)1097-0029(19990215)44:4<204::AID-JEMT2>3.0.CO;2-I. PMID 10098923. S2CID 36978646.
  6. ^ Li, Chao-Bo; Hu, Li-Li; Wang, Zhen-Dong; Zhong, Shu-Qi; Lei, Lei (22 December 2009). "Regulation of compaction initiation in mouse embryo: Regulation of compaction initiation in mouse embryo". Yi Chuan = Hereditas. 31 (12): 1177–1184. doi:10.3724/sp.j.1005.2009.01177. PMID 20042384.
  7. ^ a b c d e Richard D Cummings and Rodger P McEver, C-type lectins, Essentials of Glycobiology, 2nd Edition Cold Spring Harbor, 2009[page needed]
  8. ^ a b c d e Akira, Shizuo; Uematsu, Satoshi; Takeuchi, Osamu (February 2006). "Pathogen Recognition and Innate Immunity". Cell. 124 (4): 783–801. doi:10.1016/j.cell.2006.02.015. PMID 16497588. S2CID 14357403.
  9. ^ a b c d e Troselj, Vera; Cao, Pengbo; Wall, Daniel (March 2018). "Cell-cell recognition and social networking in bacteria: Cell recognition and social networking". Environmental Microbiology. 20 (3): 923–933. doi:10.1111/1462-2920.14005. PMC 5874169. PMID 29194914.
  10. ^ Christopher N Vassallo, P Cao, A Conklin, H Finkelstein, CS Hayes, D Wall. Infectious polymorphic toxins delivered by outer membrane exchange discriminate kin in myxobacteria. 2017. eLife Microbiology and Infectious Disease[page needed]
  11. ^ a b c d e Laura Dean. Blood group antigens are surface markers on the red blood cell membrane. Blood Groups and Red Cell Antigens. 2005. National Center for Biotechnology Information[page needed]
  12. ^ Bhide, Mangesh R; Mucha, Rastislav; Mikula, Ivan; Kisova, Lucia; Skrabana, Rostislav; Novak, Michal; Mikula, Ivan (December 2009). "Novel mutations in TLR genes cause hyporesponsiveness to Mycobacterium avium subsp. paratuberculosis infection". BMC Genetics. 10 (1): 21. doi:10.1186/1471-2156-10-21. PMC 2705378. PMID 19470169.
  13. ^ Thuong, N. T. T.; Hawn, T. R.; Thwaites, G. E.; Chau, T. T. H.; Lan, N. T. N.; Quy, H. T.; Hieu, N. T.; Aderem, A.; Hien, T. T.; Farrar, J. J.; Dunstan, S. J. (July 2007). "A polymorphism in human TLR2 is associated with increased susceptibility to tuberculous meningitis". Genes & Immunity. 8 (5): 422–428. doi:10.1038/sj.gene.6364405. PMID 17554342. S2CID 24528072.
  14. ^ Bochud, Pierre‐Yves; Hawn, Thomas R.; Siddiqui, M. Ruby; Saunderson, Paul; Britton, Sven; Abraham, Isaac; Argaw, Azeb Tadesse; Janer, Marta; Zhao, Lue Ping; Kaplan, Gilla; Aderem, Alan (15 January 2008). "Toll‐Like Receptor 2 (TLR2) Polymorphisms Are Associated with Reversal Reaction in Leprosy". The Journal of Infectious Diseases. 197 (2): 253–261. doi:10.1086/524688. PMC 3077295. PMID 18177245.
  15. ^ Tabel, Y.; Berdeli, A.; Mir, S. (December 2007). "Association of TLR2 gene Arg753Gln polymorphism with urinary tract infection in children". International Journal of Immunogenetics. 34 (6): 399–405. doi:10.1111/j.1744-313X.2007.00709.x. PMID 18001294. S2CID 35652649.
  16. ^ Fukusaki, T.; Ohara, N.; Hara, Y.; Yoshimura, A.; Yoshiura, K. (December 2007). "Evidence for association between a Toll-like receptor 4 gene polymorphism and moderate/severe periodontitis in the Japanese population". Journal of Periodontal Research. 42 (6): 541–545. doi:10.1111/j.1600-0765.2007.00979.x. PMID 17956467.
  17. ^ Hong, Jiwon; Leung, Euphemia; Fraser, Alan G; Merriman, Tony R; Vishnu, Prakash; Krissansen, Geoffrey W (November 2007). "TLR2, TLR4 and TLR9 polymorphisms and Crohn's disease in a New Zealand Caucasian cohort". Journal of Gastroenterology and Hepatology. 22 (11): 1760–1766. doi:10.1111/j.1440-1746.2006.04727.x. PMID 17914947. S2CID 20973083.

External links edit

  • YouTube Video: Pathogen Recognition in a Macrophage Cell 2020-05-06 at the Wayback Machine

December 18, 2023
cell, cell, recognition, cell, ability, distinguish, type, neighboring, cell, from, another, this, phenomenon, occurs, when, complementary, molecules, opposing, cell, surfaces, meet, receptor, cell, surface, binds, specific, ligand, nearby, cell, initiating, c. Cell cell recognition is a cell s ability to distinguish one type of neighboring cell from another 1 This phenomenon occurs when complementary molecules on opposing cell surfaces meet A receptor on one cell surface binds to its specific ligand on a nearby cell initiating a cascade of events which regulate cell behaviors ranging from simple adhesion to complex cellular differentiation 2 Like other cellular functions cell cell recognition is impacted by detrimental mutations in the genes and proteins involved and is subject to error The biological events that unfold due to cell cell recognition are important for animal development microbiomes and human medicine Two cells communicating via their respective surface molecules Contents 1 Fundamentals 2 Biological functions for intrinsic recognition 2 1 Growth and development 2 2 Cell recognition for injury response 3 Biological functions for extrinsic recognition 3 1 Pathogen recognition in the immune system 3 2 Bacterial ecology 4 Recognition of red blood cells 4 1 Blood types 5 Detrimental mutations 5 1 TLR mutations 6 References 7 External linksFundamentals editCell cell recognition occurs when two molecules restricted to the plasma membranes of different cells bind to each other triggering a response for communication cooperation transport defense and or growth Rather than induce a distal response like secreted hormones may do this type of binding requires the cells with the signalling molecules to be in close proximity with each other These events can be grouped into two main categories Intrinsic Recognition and Extrinsic Recognition 3 Intrinsic Recognition is when cells that are part of the same organism associate 3 Extrinsic Recognition is when the cell of one organism recognizes a cell from another organism like when a mammalian cell detects a microorganism in the body 3 The molecules that complete this binding consist of proteins carbohydrates and lipids resulting in a variety of glycoproteins lipoproteins and glycolipoproteins 3 Studies suggest glycan glycan interactions observed to be approximately 200 300pN also may play a role in cell cell recognition 4 Complex carbohydrates in particular have been studied to be extremely integral in cell cell recognition especially when it is recognized by complementary carbohydrates In order to ensure a proper binding site by checking the surrounding areas or securing a bond that was previously made complex carbohydrates and their complementary carbohydrates are able to create flexible interaction systems These interactions although observed to be weak have been studied in a variety of test subjects including but not limited to mouse embryonal cells corneal epithelial cells and human embryonal carcinoma cells 4 Biological functions for intrinsic recognition editGrowth and development edit One of the more basic versions of cell cell recognition for adhesion can be observed in sponges the most primitive group in the animal kingdom Sponges develop through the aggregation of individual cells into larger clusters Through membrane binding proteins and secreted ions individual sponge cells are able to coordinate aggregation while preventing fusion between different species or even different individuals 5 This was discovered when attempts to graft sponge cells from different species or individuals of the same species failed while attempts using cells from the same individual merged successfully 5 This is likely due to distinct cadherins a calcium binding membrane protein expressed by different sponge species and individuals 5 Cadherins are present in more complex organisms as well In mouse embryos E cadherin on cell membranes is responsible for the adhesion of cells needed for embryonic compaction 6 Cell recognition for injury response edit When a large multi cellular organism sustains an injury cell cell recognition is often involved in bringing certain types of cells to the site of an injury A common example of this is selectin expressing cells in animals Selectin is a receptor protein found on the membranes of leukocytes platelet cells and endothelial cells that binds membrane bound glycans 7 In response to an injury endothelial cells will express selectin which binds to glycans present on the leukocyte cell surface 7 Platelet cells which are involved in tissue repair use their selectins to associate with leukocytes on the way to the endothelial cells 7 Leukocytes then use their own selectins to recognize potential pathogens at the site of the injury 7 In this manner the appropriate cells are brought to the site of an injury to deal with immediate repair or invading microorganisms 7 Biological functions for extrinsic recognition editPathogen recognition in the immune system edit Cells with immune system recognition abilities include macrophages dentritic cells T cells and B cells 8 Cell cell recognition is especially important in the innate immune system which identifies pathogens very generally Central to this process is the binding of pattern recognition receptors PRRs of phagocytes and pathogen associated molecular patterns PAMPs in pathogenic microorganisms 8 One type of PRR is a group of integral membrane glycoproteins called toll like receptors TLRs which can recognize certain lipoproteins peptidoglycan CpG rich DNA and flagellar components in bacterial cells as well as glycoproteins and phospholipids from protozoan parasites and conidia fungal spores 8 The binding of PAMPs to TLR proteins generally results in an internal signaling cascade including a number of phosphorylations the adding of a phosphate group and ubiquitinations the adding of a small protein that marks molecules for degradation that eventually leads to the transcription of genes related to inflammation 8 The use of TLRs by cells in the innate immune system has led to an evolutionary battle between pathogenic cells developing different PAMPs that cannot be recognized and immune cells developing new membrane proteins that can recognize them 8 Bacterial ecology edit Single celled organisms can bind to each other through surface receptors for cooperation and competition This has been widely observed in bacteria For instance bacteria can attach to each other through the binding of outer membrane proteins TraA and TraB to facilitate a process called outer membrane exchange OME that allows bacterial cells to swap membrane lipids sugars and toxins 9 Cell recognition and OME can only be achieved if TraA and TraB variants from the same recognition group bind 9 These interactions can generate the physiological diversity required for antibiotic resistance in bacterial populations 10 The Escherichia coli membrane protein ChiA is involved in the process of contact dependent inhibition CDI in which it binds to receptors on rival E coli strains and releases a toxin that prevents growth of those strains while the inhibiting cell and members of that strain are protected 9 The bacterium Proteus mirabilis uses the T6SS protein to initiate swarming and destruction of other bacterial colonies upon recognition either by release of toxins or by release of signal proteins to other P mirabilis cells 9 The binding of bacterial surface receptors for adhesion has also been implicated in the formation of biofilms 9 Recognition of red blood cells editBlood types edit Red blood cells contain antigens in their plasma membranes that distinguish them as part of a specific category of blood cell These antigens can be polysaccharides glycoproteins or GPI a glycolipid linked proteins 11 Antigens range in complexity from small molecules bound to the extracellular side of the phospholipid bilayer to large membrane proteins that loop many times between both sides of the membrane 11 The smaller polysaccharide antigens classify blood cells into types A B AB and O while the larger protein antigens classify blood cells into types Rh D positive and Rh D negative 11 While the biological role of the correct blood type is unclear and may be vestigial the consequences of incorrect blood types are known to be severe 11 The same cells that recognize PAMPs on microbial pathogens may bind to the antigen of a foreign blood cell and recognize it as a pathogen because the antigen is unfamiliar 11 It is not easy to classify red blood cell recognition as intrinsic or extrinsic as a foreign cell may be recognized as part of the organism if it has the right antigens Detrimental mutations editTLR mutations edit Mutations in mammalian receptor proteins can cause disorders in cell cell recognition increasing individual susceptibility to certain pathogens and chronic conditions When mutations occurs in genes that code for TLRs the proteins can lose the ability to bind with polysaccharides lipids or proteins on the cell wall or membrane of single celled pathogens resulting in a failure of the innate immune system to respond to infection that allows disease to develop rapidly In particular mutations in the genes for TLR2 and TLR4 have been frequently implicated in increased susceptibility to pathogens 12 A threonine to cysteine mutation in the TRL2 gene has been connected to failure to recognize the Mycobacterium tuberculosis the causative agent of Tuberculosis meningitis 13 The same mutation T597C was later observed consistently with the failure to recognize Mycobacterium leprae the causative agent of Leprosy 14 An Arginine to Glutamine mutation in TRL2 Arg753Gln was connected to increased pediatric Urinary Tract Infections caused by gram positive bacteria 15 Multiple mutations in TLR4 Asp299Gly and Thr399Ile were implicated in susceptibility to the bacterial pathogens that cause Periodontitis 16 The connection of TLR mutations to Chron s Disease has also been investigated but has not yielded conclusive evidence 17 The common characteristic between these missense mutations is that the amino acid residues that are substituted have notably different side chain properties which likely contributes to the defective TLR protein function References edit Campbell et al Biology Eighth Edition 2008 Pearson Education Inc Schnaar Ronald L Research Goals Link 1 May 2010 a b c d Ajit Varki and John B Lowe Biological Roles of Glycans Essentials of Glycobiology 2nd Edition Cold Spring Harbor 2009 page needed a b Bucior Iwona Burger Max M October 2004 Carbohydrate carbohydrate interactions in cell recognition Current Opinion in Structural Biology 14 5 631 637 doi 10 1016 j sbi 2004 08 006 PMID 15465325 a b c Fernandez Busquets Xavier Burger Max M 1999 Cell adhesion and histocompatibility in sponges Microscopy Research and Technique 44 4 204 218 doi 10 1002 SICI 1097 0029 19990215 44 4 lt 204 AID JEMT2 gt 3 0 CO 2 I PMID 10098923 S2CID 36978646 Li Chao Bo Hu Li Li Wang Zhen Dong Zhong Shu Qi Lei Lei 22 December 2009 Regulation of compaction initiation in mouse embryo Regulation of compaction initiation in mouse embryo Yi Chuan Hereditas 31 12 1177 1184 doi 10 3724 sp j 1005 2009 01177 PMID 20042384 a b c d e Richard D Cummings and Rodger P McEver C type lectins Essentials of Glycobiology 2nd Edition Cold Spring Harbor 2009 page needed a b c d e Akira Shizuo Uematsu Satoshi Takeuchi Osamu February 2006 Pathogen Recognition and Innate Immunity Cell 124 4 783 801 doi 10 1016 j cell 2006 02 015 PMID 16497588 S2CID 14357403 a b c d e Troselj Vera Cao Pengbo Wall Daniel March 2018 Cell cell recognition and social networking in bacteria Cell recognition and social networking Environmental Microbiology 20 3 923 933 doi 10 1111 1462 2920 14005 PMC 5874169 PMID 29194914 Christopher N Vassallo P Cao A Conklin H Finkelstein CS Hayes D Wall Infectious polymorphic toxins delivered by outer membrane exchange discriminate kin in myxobacteria 2017 eLife Microbiology and Infectious Disease page needed a b c d e Laura Dean Blood group antigens are surface markers on the red blood cell membrane Blood Groups and Red Cell Antigens 2005 National Center for Biotechnology Information page needed Bhide Mangesh R Mucha Rastislav Mikula Ivan Kisova Lucia Skrabana Rostislav Novak Michal Mikula Ivan December 2009 Novel mutations in TLR genes cause hyporesponsiveness to Mycobacterium avium subsp paratuberculosis infection BMC Genetics 10 1 21 doi 10 1186 1471 2156 10 21 PMC 2705378 PMID 19470169 Thuong N T T Hawn T R Thwaites G E Chau T T H Lan N T N Quy H T Hieu N T Aderem A Hien T T Farrar J J Dunstan S J July 2007 A polymorphism in human TLR2 is associated with increased susceptibility to tuberculous meningitis Genes amp Immunity 8 5 422 428 doi 10 1038 sj gene 6364405 PMID 17554342 S2CID 24528072 Bochud Pierre Yves Hawn Thomas R Siddiqui M Ruby Saunderson Paul Britton Sven Abraham Isaac Argaw Azeb Tadesse Janer Marta Zhao Lue Ping Kaplan Gilla Aderem Alan 15 January 2008 Toll Like Receptor 2 TLR2 Polymorphisms Are Associated with Reversal Reaction in Leprosy The Journal of Infectious Diseases 197 2 253 261 doi 10 1086 524688 PMC 3077295 PMID 18177245 Tabel Y Berdeli A Mir S December 2007 Association of TLR2 gene Arg753Gln polymorphism with urinary tract infection in children International Journal of Immunogenetics 34 6 399 405 doi 10 1111 j 1744 313X 2007 00709 x PMID 18001294 S2CID 35652649 Fukusaki T Ohara N Hara Y Yoshimura A Yoshiura K December 2007 Evidence for association between a Toll like receptor 4 gene polymorphism and moderate severe periodontitis in the Japanese population Journal of Periodontal Research 42 6 541 545 doi 10 1111 j 1600 0765 2007 00979 x PMID 17956467 Hong Jiwon Leung Euphemia Fraser Alan G Merriman Tony R Vishnu Prakash Krissansen Geoffrey W November 2007 TLR2 TLR4 and TLR9 polymorphisms and Crohn s disease in a New Zealand Caucasian cohort Journal of Gastroenterology and Hepatology 22 11 1760 1766 doi 10 1111 j 1440 1746 2006 04727 x PMID 17914947 S2CID 20973083 External links editYouTube Video Pathogen Recognition in a Macrophage Cell Archived 2020 05 06 at the Wayback Machine Retrieved from https en 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